DE2307058C3 - Multi-slit thyratron - Google Patents

Description

The invention relates to a multi-slit thyratron with at least one gradient grid, in which the electrodes forming the gradient grid are connected to a voltage source.

From DT-AS 15 39 927 a multi-slit thyratron of the type described above is known. Such Thyratron designs have significant advantages over other thyratron arrangements abe; on the other hand, has the disadvantage that ih-e Lifespan is unpredictable and in most cases extremely short. It happens again and again before that such thyratrons become unusable after a few seconds of operation due to damage, which occur on one or more gradient grids of the thyratron.

Building on this prior art, the invention is based on the object of a multi-slit thyratron to create with at least one gradient grating of the type mentioned, its service life by reliably avoiding damage to the gradient grid electrodes is particularly high.

The invention provides for solving this problem.

that between the voltage source and that electrode of an electrode pair forming a gradient grid, which is located furthest away from the cathode, a current limiting device is provided.

It was assumed that the above-mentioned difficulties as a result of the parasitic Capacity occur which is assigned to the power supply connected to the gradient grid is. Whether or not this assumption is correct, it has been found that the use of a Current limiting device for that electrode of an electrode pair forming a gradient grid, which is located furthest away from the cathode, a significant increase in service life and the reliability of a multi-gap thyratron. By such a current limitation the risk of an excessive voltage between the electrodes on the gradient grid is reduced builds up, causing lasting damage to the electrodes of the thyratron, which limits the service life be avoided.

Furthermore, there is the advantage that multi-gap thyratron with the current limitation according to the invention achieve the predicted performance more reliably than multi-gap thyratrons using this device do not exhibit.

The current limitation provided according to the invention can be implemented in very diverse ways.

Thus, there is a preferred embodiment of the invention in which the two form a gradient grating Electrodes connected to one another by a resistor that maintains a voltage difference are, which is supplied with the supply voltage for the gradient grid at one of its end points is, in that between this end point of the resistance and the supply voltage source c at least a siromblimiting resistor is provided.

With this arrangement, the object of the invention is achieved regardless of whether the current-limiting resistor is connected to the end point of the resistance maintaining the voltage difference which is connected to that electrode of the electrode pair forming the gradient grating which is arranged farthest from the cathode, or with the other end point of the voltage difference maintaining resistor connected to the electrode closer to the cathode.

In a further advantageous embodiment of the invention it is provided that the current limiting device is constructed in such a way that two resistors each have one of their endpoints with one of the das Gradient grid forming electrodes are connected and that the other two end points with each other and are connected to the supply voltage source.

Another preferred embodiment of the invention is realized in that the current limiting device is constructed so that two resistors are each connected to one of their end points with one of the electrodes forming the gradient grid and that the other two end points of the two resistors with the opposite ends of one Resistance are connected, which supplies the supply voltage for the gradient grating in a Voltage divider is included.

Another embodiment provides that the current limiting device is constructed so that two resistors, each with one of their end points with one of the electrodes forming the gradient grid are connected and that the other two endpoints of the two resistors are jointly connected to one End of another resistor are placed, whose free end to the voltage supply source for the gradient grid is connected.

It goes without saying that the term "resistance" used up to now also includes any Combinations of resistor elements are to be understood as being equivalent to a single resistor are.

Although in the embodiments described above, the current limitation is purely ohmic Components was carried out, it is also possible to use inductive or capacitive elements alone or to use in combination with one another and id / or ohmic elements. So another one stands out Embodiment of the Krlindiing in that a? -O Capacitor is connected between the two electrodes forming a gradient grid.

This capacitor helps to limit the current insofar as it is capable of briefly occurring, short-circuit high-frequency voltage peaks between the two electrodes forming a gradient grid or to vaporize so strongly that the current surges associated with these voltage peaks are reduced to a tolerable level Stay limited

This aid can of course also be used in addition to any of the arrangements described above used by resistance elements.

Another variant can also be provided be that a nonlinear element, such as a voltage dependent resistor, between the two a gradient grid forming electrodes is connected.

An embodiment with the use of inductive elements is realized in that the current limiting device is formed by a delay line. This can in particular be carried out in this way that the delay line is a coaxial cable and that a balancing resistor between it and the voltage supply source for the gradient grating is switched. It can also be provided that part of the connection, which is that electrode of a pair of electrodes forming a gradient lattice, which is closest to the cathode, connects to the supply voltage source, through the outer conductor of the coaxial cable is formed.

The invention is described below, for example, with reference to the drawing. In this shows

F i g. 1 a multi-slit thyratron of conventional design,

F i g. 2 to 6 and 8 multi-gap thyratrons with a current limitation implemented by resistors,

F i g. 7 a multi-slit thyratron whose current limitation is implemented by means of an inductive element is and

F i g. 9 a multi-slit thyratron in which a capacitance is used to limit the current.

The in Fig. 1 shown thyratron has a ceramic piston 1, within which there is a cathode 2, a control grid 3, two adjacent electrodes 4 and 5, which form a gradient grid, and an anode 6 are located. Since this thyratron has a gradient grid, it is a design with two columns, the first voltage level gap 7 being between the control grid 3 and the electrode 4, while the second voltage level gap 8 lies between the electrode 5 and the anode 6. the The electrodes of the thyratron are fed by a voltage divider that is connected in parallel to the thyratron is. This voltage divider consists of resistors 9 and 10. One end of the voltage divider is connected to the cathode and grounded, the other end of the voltage divider is to the anode connected, while the intermediate point 11 with the electrode 4 via a resistor 12 and with the electrode 5 is directly connected. The resistor 12, which in this way is practically between the two electrodes 4 and 5, is used during operation to create a voltage difference between the two electrodes maintain. Although in FIG. 1 a voltage divider is shown as it is in most Cases used to power the electrodes 4 and 5, it is also known to be an independent Provide supply for these two electrodes by placing a point corresponding to point 11 above a resistor is connected to a point of fixed voltage. In operation, the two will Gradient grating forming electrodes 4 and 5 are held at the same potential before being conductive. When the conductive state begins, a voltage occurs between them which ensures that the Main discharge first through the voltage level maintenance

column and in it through the gradient grid he follows. In the case of a thyratron with more than two voltage stability gaps and accordingly more as a gradient grid, each gradient grid works in a similar way, but with a starting voltage, which becomes progressively higher for the gradient grating closer to the anode.

The in Fig. The multi-slit thyratron shown in FIG. 2, like the one connected in parallel, is a voltage divider The power supply set up is identical to that in FIG. 1 shown arrangement. However, they are devices to limit the current for the electrode of the gradient grid, which is located closer to the anode 6, d. H. provided for the electrode 5 in order to separate it from the capacitance 13 assigned to the voltage divider 9, 10 to decouple. These devices consist in the present case of a resistor 14 between the point 11 lying in the voltage divider 9, 10 on the one hand and the point connected to the electrode 5 End point of the resistor 12 is switched on the other hand. In operation, the resistor 12 is used again to the required voltage difference between the electrodes 4 and 5 to maintain. Resistance 14 causes the current to be limited by the capacitance 13 assigned to the voltage divider 9, 10 the electrodes 4 and 5 flows.

The in F i g. The arrangement shown in FIG. 3 is that in FIG. 2 shown the same with the exception that the The current limiting resistor 14 is connected on the electrode side to the end point of the resistor 12 which is also the electrode 4. In this case, the voltage divider 9, 10 assigned capacitance 13 is discharged through the conduction state between cathode 2 and electrode 4. The stray capacitance now connected to the electrode 5 is largely that of the thyratron itself, the is significantly smaller than the capacitance 13 assigned to the voltage divider 9, 10. Inside the thyratron there is a voltage dividing effect (due to the division of capacities between the electrodes), with the result that the voltage between the electrodes 4 and 5 is lowered.

In the arrangement according to FIG. 4 contain the power supply lines for the two electrodes 4 and 5, current limiting resistors 16 and 15, which are both serve to maintain the desired voltage difference between these two electrodes, as well as to limit the current of the capacitance 13 assigned to the voltage divider 9, 10 initially flows into the two electrodes.

The in F i g. The arrangement shown in FIG. 5 is the arrangement from FIG. 4 similar in that the power supply lines to the two electrodes 4 and 5 also current limiting resistors 16 and 15 th contained. In this case, however, the voltage divider ends of these resistors 15 and 16 are not g together and to a common point (11 in F i. 4 ) connected to the voltage divider 9, 10, but to the opposite ends of a resistor 17 connected between the resistors 9 and 10 in the voltage divider F i g. 4 the resistors 16 and 15 limit the current which initially flows from the capacitance 13 assigned to the voltage divider 9, 10 to the electrodes 4 and 5.

In the embodiment according to FIG. 6 the voltage supply for electrodes 4 and 5 is not voter a voltage connected in parallel to the thyratron

ίο divider derived, as with the off described above guide forms, but from a separate voltage source 18 via a resistor 19. in the rest the arrangement is similar to the arrangement as shown in FIG. 4 is shown.

In Fig. 7 is the use of an inductive element, in this case a coaxial line 20, all Current limiting element shown. For this purpose, the coaxial line 20 is in the power supply line for the electrode 5. A balancing resistor 21 is connected in series with the coaxial line 20. The Span The power supply for the electrode 4 is expediently carried out via the outer conductor of the coaxial line 20.

F i g. 8 shows an embodiment of the invention

in application to a multi-slit thyratron with flour than two columns (in the present case with three columns and more than one gradient grid (in the present case with two gradient grids). The additional space is denoted by 22, while the additional gradient grid by two electrodes 23 and 24 formed will. The power supply for each gradient grid is similar to that for the individual gradient grid of the arrangement according to FIG. 4 carried out. Di <resistances in each of the feed lines to the to Additional electrodes 23 and 24 are marked 25 and 26 be. In operation, the resistors 15 and U and the resistors 25 and 26 have exactly the same effect as the corresponding resistors 15 and 26 16 in Fig. 4. As with the known arrangements, the nominal voltage of the gradient grating 4, 5 is calculated as follows specifies that it is higher than the nominal voltage of the Gra dientengitter 22,24, which is achieved by installing a wide Ren resistor 27 is reached in the voltage divider.

In the embodiment according to FIG. 9, the current limitation between the electrode 5 and the capacitance 1 assigned to the voltage divider 9, 10 is effected by a capacitance. This arrangement corresponds to that of FIG. 1, with an additional capacitor 27 between electrodes 4 and 5 being used.

These basic formers described above can be combined in many cases. For example , in all the embodiments according to FIG . 2 to 8 capacitors are connected between the two electrodes of a gradient grid, wit it in F i g. 9 is shown. Furthermore, in the embodiments according to FIGS. 2 to 6 and 8, the current limiting resistors in many cases hung by inductive components, for example by delay lines or cables are replaced or combined with these .

For this purpose 2 sheets of drawings

Claims (10)

Patent claims: 1. Multi-slit thyratron with at least one gradient grid, in which the gradient grid forming electrodes are connected to a voltage source, characterized in that that between the voltage source (9, 10) and that electrode (5) of a gradient grid forming Electrode pair (4, 5), which is arranged furthest away from the cathode (2), a current limiting device (14) is provided. 2. Multi-slit thyratron according to claim 1, in which the two electrodes forming a gradient grid interconnected by a resistor maintaining a voltage difference are, which is supplied with the supply voltage for the gradient grid at one of its end points is, characterized in that between this end point of the resistor (12) and the supply voltage source (11) at least one current-limiting resistor (14) is provided. 3. Multi-gap thyratron according to claim 1, characterized in that the current limiting device is constructed so that two resistors (15,16) each with one of their end points with a of the electrodes (4, 5) forming the gradient grid are connected and that the other two end points of the two resistors (15.16) are connected to one another and to the supply voltage source (11) are. 4. Multi-gap thyratron according to claim 1, characterized in that the S'rombbegrenzungsvorrichtung is constructed so that two resistors (15,16) each with one of their end points with a of the electrodes (4, 5) forming the gradient grid are connected and that the other two end points of the two resistors (15, 16) connected to the opposite ends of a resistor (17) are in a voltage divider that supplies the supply voltage for the gradient grating (9,10,17) is included. 5. Multi-gap thyratron according to claim 1, characterized in that the current limiting device is constructed so that two resistors (15, 16) each with one of their end points with a of the electrodes (4, 5) forming the gradient grid are connected and that the other two end points of the two resistors (15, 16) placed together at one end of a further resistor (19) whose free end is connected to the voltage supply source for the gradient grating. 6. Multi-gap thyratron according to one of the preceding claims, characterized in that a capacitor (27) is connected between the two electrodes (4, 5) forming a gradient grid is. 7. Multi-slit thyralron according to one of the preceding Claims, characterized in that a non-linear element, for example a voltage-dependent Resistance, connected between the two electrodes (4, 5) forming a gradient grid is. 8. Mchrspalt thyratron according to claim I, characterized characterized in that the current limiting device is formed by a delay line (20) will. 9. Multi-slit thyratron according to / "« Proverb 8, thereby characterized in that the delay line (20) is a coaxial cable and that a balancing resistor (21) between this and the voltage supply source (9, 10) for the gradient grid is switched. 10. Multi-gap thyratron according to claim 9, characterized in that part of the compound, that electrode (4) of an electrode pair (4, 5) forming a gradient grid, that of the cathode (2) is closest to each other, connects to the supply voltage source (9, 10) through the Outer conductor of the coaxial cable is formed.